The present invention relates to a system and a method for transferring glass items from machines for shaping glass items of the type that comprises: a rotary cooling platform for receiving, cooling and conveying items formed immediately prior in molds of said shaping machine to a conveyor belt, the rotary cooling platform having a rotational motion towards the left and towards the right, from a first position for receiving items to a second delivery position facing said conveyor belt; first drive means located under the rotary cooling platform in order to rotate same with said rotational motion from said position for receiving items to said second position for delivering items and from said position for delivering items to said position for receiving items; and a pushing mechanism coupled onto the rotary platform, the pushing mechanism being aligned in the first receiving position with each of the recently shaped items of the molds, the pushing mechanism being translated together with said rotary cooling platform from the first position for receiving items to the second position for delivering items; the pushing mechanism having a to-and-fro motion in the second delivery position for pushing the items along a diagonal path, at constant speed, from the rotary cooling platform positioned in said second position towards the conveyor belt in order to place the items aligned above same.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

The present invention relates to a system and a method for transferring glass items from machines for shaping glass items of the type that comprises: a rotary cooling platform for receiving, cooling and conveying items formed immediately prior in molds of said shaping machine to a conveyor belt, the rotary cooling platform having a rotational motion towards the left and towards the right, from a first position for receiving items to a second delivery position facing said conveyor belt; first drive means located under the rotary cooling platform in order to rotate same with said rotational motion from said position for receiving items to said second position for delivering items and from said position for delivering items to said position for receiving items; and a pushing mechanism coupled onto the rotary platform, the pushing mechanism being aligned in the first receiving position with each of the recently shaped items of the molds, the pushing mechanism being translated together with said rotary cooling platform from the first position for receiving items to the second position for delivering items; the pushing mechanism having a to-and-fro motion in the second delivery position for pushing the items along a diagonal path, at constant speed, from the rotary cooling platform positioned in said second position towards the conveyor belt in order to place the items aligned above same.

A turbine engine has: a first member (22) having a surface bearing an abradable coating, the abradable coating (36) being at least 90% by weight ceramic; and a second member (24) having a surface bearing an abrasive coating. The abrasive coating (56) has a metallic matrix (64) and a ceramic oxide abrasive (66) held by the metallic matrix, the first member and second member mounted for relative rotation with the abrasive coating facing or contacting the abradable coating. At least 50% by weight of the ceramic abrasive has a melting point at least 400K higher than a melting point of at least 20% by weight of the ceramic of the abradable coating.

A turbine engine has: a first member (22) having a surface bearing an abradable coating, the abradable coating (36) being at least 90% by weight ceramic; and a second member (24) having a surface bearing an abrasive coating. The abrasive coating (56) has a metallic matrix (64) and a ceramic oxide abrasive (66) held by the metallic matrix, the first member and second member mounted for relative rotation with the abrasive coating facing or contacting the abradable coating. At least 50% by weight of the ceramic abrasive has a melting point at least 400K higher than a melting point of at least 20% by weight of the ceramic of the abradable coating.